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United States Patent |
5,165,084
|
Chang
|
November 17, 1992
|
System and method for measuring changes in sea level
Abstract
A system for determining changes in sea level based on the measurement of
distance between capacitive elements. The system includes an electrically
conductive sphere 17, 117 mounted on an electrically non-conductive buoy
13, 113, positioned a predetermined distance above sea level with the
sphere and the sea (earth) acting as capacitive elements separated by the
predetermined distance. The system also includes an ion source 25 for
imparting charge to the sphere 17, a clock 23, an electrometer 21 for
detecting (measuring) the voltage on the sphere at selected clock times.
In an alternative embodiment, the ion source and electrometer are replaced
with a swept frequency voltage generator 121, an inductor 127, and an
ammeter 125. The inductor 127 and the sphere 117 form an LC component. In
response to voltages of various frequencies applied to the sphere 117 by
the generator 121, the ammeter 125 at each clock time, detects (measures)
the current at the resonant frequency of the LC component. The measured
voltages (or currents) are then averaged over time to compensate for wave
motion (bobbing) of the buoy and dimensional changes in the buoy due to
thermal (solar) effects. From each averaged voltage (or current)
capacitance and sea level are calculated, and the change in sea level
noted.
Inventors:
|
Chang; David B. (Tustin, CA)
|
Assignee:
|
Hughes Aircraft Company (Los Angeles, CA)
|
Appl. No.:
|
659761 |
Filed:
|
February 25, 1991 |
Current U.S. Class: |
361/284; 73/304C |
Intern'l Class: |
G01F 073/26 |
Field of Search: |
361/284
73/304 C
324/72
340/207
367/12
|
References Cited
U.S. Patent Documents
2768368 | Oct., 1956 | Crane et al. | 340/207.
|
2817234 | Dec., 1957 | Campbell | 73/304.
|
3873050 | Mar., 1975 | Hill | 324/72.
|
4194395 | Mar., 1980 | Wood | 73/304.
|
5077696 | Dec., 1991 | McEachern et al. | 367/12.
|
Primary Examiner: Griffin; Donald A.
Attorney, Agent or Firm: Sales; Michael W., Denson-Low; Wanda K.
Claims
What is claimed is:
1. A system mountable on an electronically non-conductive buoy for
determining sea level, the system comprising:
a spherical electrically-conductive member mountable on the buoy at a
predetermined distance above the surface of the sea, for forming a
capacitive element relative to the sea;
an ion source mounted on the buoy proximate to the spherical member and
above the sea for applying a charge to said member;
a clock means mounted on the buoy above the sea for producing clock
signals; and
a detector means, mounted on the buoy above the sea and forming an
electrical circuit with the clock means, the ion source, the spherical
member, and the sea, for detecting, at each clock signal, the voltage on
said spherical member relative to the sea, said voltage being
representative of the capacitance of said spherical member and
representative of the level of the sea.
2. The system as in claim 1 wherein the ion source includes a shield
responsive to the clock signal for exposing the spherical member to the
ion source for a predetermined period of time, then shielding the
spherical member from the ion source.
3. The system as in claim 2 wherein said detector means averages the
detected voltages over the number of clock signals produced by the clock
means.
4. The system as in claim 3 wherein said detector means is a recording
electrometer.
5. The system as in claim 4 where the predetermined distance is at least
fifty meters.
6. A system for determining sea level comprising:
an electrically non-conductive buoy for floating in the sea;
a spherical electrically-conductive member mounted on the buoy and disposed
a predetermined distance above the surface of the sea, forming a
capacitive element relative to the sea;
an ion source mounted on the buoy proximate to the spherical member for
applying a charge to said member;
a clock means mounted on the buoy above the sea for producing clock
signals; and
a detector means, mounted on the buoy above the sea and forming an
electrical circuit with the clock means, the spherical member, the ion
source, and the sea, for detecting, at each clock signal, the voltage on
said spherical member relative to the sea, said voltage being
representative of the capacitance of said spherical member and
representative of the level of the sea.
7. The system as in claim 6 wherein the ion source includes a shield
responsive to the clock signal for exposing the spherical member to the
ion source for a predetermined period of time, then shielding the
spherical member from the ion source.
8. The system as in claim 7 wherein said detector means averages the
detected voltages over the number of clock signals produced by the clock
means.
9. A system mountable on an electronically non-conductive buoy for
determining sea level, the system comprising:
a spherical electrically-conductive member mountable on the buoy at a
predetermined distance above the surface of the sea, for forming a
capacitive element relative to the sea;
a clock means mounted on the buoy above the sea for producing clock
signals;
a voltage generation means mounted on the buoy above the sea for applying
voltages of various frequencies to the spherical member;
an inductor means mounted on the buoy above the sea, and coupled to the
spherical member forming an LC component with a resonant frequency; and
a detector means mounted on the buoy above the sea and forming an
electrical circuit with the inductor means, the voltage generation means,
the clock means, the spherical member, and the sea, for detecting, at each
clock signal, the current at the resonant frequency, said current being
representative of the capacitance of said spherical member and
representative of the level of the sea.
10. The system as in claim 9 wherein said detector means averages said
detected currents over the number of clock signals produced by the clock
means.
11. The system as in claim 10 wherein said detector means is a recording
ammeter.
12. The system as in claim 11 wherein said voltage generation means is a
swept frequency voltage generator.
13. A system for determining sea level, the system comprising:
an electrically non-conductive buoy for floating in a sea;
a spherical electrically-conductive member mounted on the buoy and disposed
a predetermined distance above the surface of the sea, forming a
capacitive element relative to the sea;
a clock means mounted on the buoy above the sea for producing clock
signals;
a voltage generation means mounted on the buoy above the sea for applying
voltages of various frequencies to the spherical member;
an inductor means mounted on the buoy above the sea, and coupled to the
spherical member forming an LC component with a resonant frequency; and
a detector means mounted on the buoy above the sea and forming an
electrical circuit with the inductor means, the voltage generation means,
the clock means, the spherical member, and the sea, for detecting, at each
clock signal, the current at the resonant frequency, said current being
representative of the capacitance of said spherical member and
representative of the level of the sea.
14. The system as in claim 13 wherein said detector means averages said
detected currents over the number of clock signals produced by the clock
means.
15. The system as in claim 14 wherein said detector means is a recording
ammeter.
16. The system as in claim 15 wherein said voltage generation means is a
swept frequency voltage generator.
17. A method of determining sea level using an electrically non-conductive
buoy, the method comprising the steps of:
applying a charge to an electrically conductive sphere mounted on the buoy
at a predetermined distance above the surface of the sea, the sphere
forming a capacitive element relative to the sea;
producing a series of clock signals; and
detecting, at each clock signal, the voltage on the sphere relative to the
sea, said voltage being representative of the capacitance of the sphere
and level of the sea.
18. Method of determining sea level using an electrically non-conductive
buoy, the method comprising the steps of:
mounting an electrically conductive sphere on the buoy at a predetermined
distance above the surface of the sea, the sphere forming a capacitive
element relative to the sea;
coupling an inductive element to the capacitive element, forming an LC
component;
producing a series of clock signals;
applying voltages of various frequencies to the sphere; and
detecting, at each clock signal, the current at the resonant frequency of
the LC component, said current being representative of the capacitance of
the sphere, and representative of the level of the sea.
Description
BACKGROUND OF THE INVENTION
This invention relates to the measurement of varying parameters of
capacitive elements generally, and particularly to the measurement of
changes in sea level upon characterization of the earth as a capacitive
element.
Slight changes in sea level (e.g., changes of the order of about 0.6 cm per
year) may occur as a result of global warming. However, present satellite
measurements of sea level do not reflect such small changes. For example,
the GEOS 3 and SEASAT satellites presently measure sea level changes to
about 10 cm of accuracy.
Also, satellite launchings are expensive; so are space-approved satellite
instrumentation.
What is needed and would be useful, therefore, is a less expensive system
which could detect slight sea level changes that may be even less than 10
cm, and provide accurate measurements of such changes.
SUMMARY OF THE INVENTION
The present invention provides a system for determining changes in sea
level that is substantially less expensive than satellite systems, and
that can detect slight sea level changes which may be less than 10 cm/yr.
According to one aspect of the invention, the system, which is mountable on
an electronically non-conductive buoy, includes an electrically-conductive
sphere mountable on the buoy at a predetermined distance above the surface
of the sea, for forming a capacitive element relative to the sea; an ion
source mounted on the buoy proximate to the sphere and above the sea for
applying a charge to the sphere; a clock mounted on the buoy above the sea
for producing clock signals; and a detector (electrometer), mounted on the
buoy above the sea and forming an electrical circuit with the clock, the
ion source, the sphere, and the sea, for detecting, at each clock signal,
the voltage on the sphere relative to the sea, said voltage being
representative of the capacitance of the sphere and representative of the
level of the sea.
According to another aspect of the invention, the system, which is
mountable on an electronically non-conductive buoy, includes an
electrically-conductive sphere mountable on the buoy at a predetermined
distance above the surface of the sea, for forming a capacitive element
relative to the sea; a clock mounted on the buoy above the sea for
producing clock signals; a swept frequency voltage generator mounted on
the buoy above the sea for applying voltages of various frequencies to the
sphere; an inductor mounted on the buoy above the sea, and coupled to the
sphere, forming an LC component with a resonant frequency; and a detector
(ammeter) mounted on the buoy above the sea and forming an electrical
circuit with the inductor, the voltage generator, the clock, the sphere,
and the sea, for detecting, at each clock signal, the current at the
resonant frequency, said current being representative of the capacitance
of the sphere and representative of the level of the sea.
According to still another aspect of the invention, a method of determining
sea level using an electrically non-conductive buoy is provided, including
applying a charge to an electrically conductive sphere mounted on the buoy
at a predetermined distance above the surface of the sea, the sphere
forming a capacitive element relative to the sea; producing a series of
clock signals; and detecting, at each clock signal, the voltage on the
sphere relative to the sea, the voltage being representative of the
capacitance of the sphere and level of the sea.
According to a further aspect of the invention, a method of determining sea
level using an electrically non-conductive buoy is provided, including the
steps of: mounting an electrically conductive sphere on the buoy at a
predetermined distance above the surface of the sea, the sphere forming a
capacitive element relative to the sea; coupling an inductive element to
the capacitive element, forming an LC component; producing a series of
clock signals; applying voltages of various frequencies to the sphere; and
detecting, at each clock signal, the current at the resonant frequency of
the LC component, the current being representative of the capacitance of
the sphere, and representative of the level of the sea.
In the embodiments described above, the detectors (electrometer/ammeter)
each includes an averaging circuit for averaging the detected (measured)
value (voltage/current) over time (i.e., over the number of clock signals)
in order to compensate for factors such as wave motion (bobbing of the
buoy) and dimensional changes in the buoy due to thermal (solar) effects.
BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1 is a diagrammatic illustration of a system of the present invention
mounted on a buoy (an electrically non-conductive floating structure);
FIG. 2 is a graphic illustration of capacitive elements formed by the earth
(and sea) and a conductive sphere mounted on the buoy;
FIG. 3 is a diagrammatic illustration of an alternative embodiment of a
system of the present invention;
FIG. 4 is a waveform diagram showing a current value (indicative of sea
level) detected by the system of FIG. 3.
DESCRIPTION OF THE PREFERRED EMBODIMENT
Referring now to FIG. 1, there is shown a system 11 of the present
invention mounted on a floating marine structure or buoy 13, the buoy
having an electrically non-conductive structure 15. The system comprises a
electrically conductive sphere 17 (e.g., a stainless steel sphere of
radius "a" fixedly mounted to the structure 15, and disposed a
predetermined fixed distance "d" from the surface of the sea (earth) 19.
The distance "d", which may be fifty meters, for example, is measured from
the center of the sphere 17 to the surface of the sea 19. The system 11
includes an electrometer (recording voltmeter) 21, a clock 23 for
providing clock (timing) signals, and an ion radiation source 25 (e.g.,
Carbon 14) with a time-controlled shield 27. The sphere 17, electrometer
21, and clock 23 are conductively coupled by cable 24 and form a circuit,
with the sea as electrical ground. The radiation source 25 is used to
apply (induce) a charge Q on the sphere 17 at selected times (e.g., every
hour) under control of clock 23, and the shield 25 is used to shield the
sphere 17 from the source 23. The electrometer 21 is then used to
determine, at the selected times (during a predetermined period, e.g.,
every hour), the change in voltage of the sphere 17 relative to the earth
as the charge Q decays. From this change in voltage, the change in
capacitance of the sphere relative to the earth is determined. Knowledge
of the change in capacitance provides information about the change in sea
level, as explained below.
As shown in FIG. 2, the earth may be considered a conductivity globe 29
with radius "a". Then a charge q (e.g., a charge placed on sphere 17 by
source 23) located at a distance "b" from the center of the globe may be
said to have an associated image charge q'):
##EQU1##
a distance a.sup.2 /b from the center of the globe.
In which event, the voltage at the location 31 of the charge (q) may be
expressed as:
##EQU2##
but, since
##EQU3##
then V may be expressed as:
##EQU4##
which reduces to
##EQU5##
which may be rewritten as,
##EQU6##
and .delta.c/c may be expressed in terms of .delta.v/v as follows:
##EQU7##
From the change in capacitance value .delta.c/c shown above in equation
(7), the difference in radius (.delta.a), representing a rise or fall in
sea level, can then be determined, as follows:
##EQU8##
For a rise in sea level 0.6 cm (i.e., .delta.a=0.6 cm), for example, the
value .delta.c/c (shown in equation (7) above) would be found to be:
##EQU9##
where a=6.437.times.10.sup.8 cm (or 4000 miles)
and d=5.times.10.sup.3 cm.
FIG. 3 shows an alternative embodiment (system 111) of the invention. Like
that shown in FIG. 1, the system 111 is fixedly mounted on a
non-electrically conductive buoy 113. The system comprises an electrically
conductive sphere 117 fixedly mounted to the buoy 113 and disposed a
predetermined fixed distance "d" from the surface of the sea 119. The
system 111 includes a swept frequency voltage generator 121, a clock 123,
a recording ammeter 125 and an inductor 127, conductively coupled to the
sphere 117 and forming a circuit with the sea 119.
The sphere 117 and inductor 127 are regarded as elements of an LC circuit,
and the capacitance (C) associated with sphere 117 is determined in terms
of the resonant angular frequency (.omega..sub.o) of the LC circuit, as
described below. Under control of clock 123 (i.e., at selected times as
determined by the clock), the generator 121 applies voltages of different
frequencies (.omega.) to sphere 117. Ammeter 125 measures the levels of
current (I) following in the circuit as a result of the applied voltages,
and records the maximum current (I.sub..omega.) and the frequency
(.omega..sub.o) at the maximum current. FIG. 4, which is a graph of
current (I.sub..omega.) as a function of frequency (.omega.) shows that
the maximum current (I.sub..omega.) occurs at the resonant frequency
(.omega..sub.o) of the LC circuit. With .omega..sub.o known (recorded),
the capacitance (c) of the sphere 117 may then be determined (using the
known relationship
##EQU10##
as follows:
##EQU11##
By substituting in equation (8) the value for C from equation (9), the
difference in radius (.delta.a), representing a rise or fall in sea level,
can then be expressed as:
##EQU12##
Moreover, the change .delta.C may be expressed in terms of the measured
change .delta..omega..sub.2 in the resonance frequency by
##EQU13##
In both embodiments described above, the detectors (the electrometer 21
shown in FIG. 1, and the over time (i.e., over the number of clock
signals), in order to compensate for factors such as wave motion and
bobbing of the buoy and dimensional changes in the structure of the buoy
due to thermal (solar) effects.
While the fundamental features of the invention have been shown and
described, it should be understood that various substitutions,
modifications, and variations may be made by those skilled in the art
without departing from the spirit or scope of the invention. Accordingly,
all such modifications and variations are included within the scope of the
invention as defined by the following claims.
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